JPH0370828B2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention has a card insertion slot and a card return slot, has a second card loading function, and is capable of reliably performing card loading and returning operations. The present invention relates to a card processing device.

[Prior art]

Card processing devices that are attached to various devices that provide services using cards, such as magnetic card public telephones, and that have a card insertion slot and a card return slot and allow you to insert a spare card have conventionally had a long transportation path and a complicated loading mechanism. Therefore, the disadvantage is that the device becomes large and expensive. Additionally, because the card insertion slot and card return slot were too far apart, users sometimes forgot their return cards, resulting in poor service quality.

Therefore, in order to solve this problem, a card return slot is provided close to the card insertion slot, and the card intake passage, card processing conveyance passage, and card return passage are arranged in a Y-shape. A card processing device is conceivable in which a card is introduced into a card processing conveyance path using a take-in mechanism, and the card is guided into a card return path by moving the card in the card processing conveyance path in a direction opposite to the take-in direction. The challenge with this device is to create a mechanism that can reliably take in, process, and return cards whose degree of bending is within the permissible range while using minimal power. Naturally, it is also desirable to reduce the number of parts, improve assembly workability, and reduce costs.

[Summary of the invention]

The present invention has been made in response to the above-mentioned demands, and includes a card insertion slot, a card return slot provided adjacent to the card insertion slot, and a card waiting passage whose one end is connected to the card insertion slot. and,
One end of the passage is connected to the card return opening, a middle part of the passage is connectable to the other end of the card waiting passage, and the part from the card return opening to the middle part of the passage is a card return passage, a card processing return passage whose middle portion is a card processing passage; a card take-in roller mechanism disposed above and below the card waiting passage so as to face each other with a gap at least equal to the thickness of the card; A shutter mechanism provided near the end of the waiting passage, a card transport mechanism for moving the card along the card processing return passage, and a part of the driving force of this card transport mechanism is transferred to the upper or lower part of the card waiting passage. A driving force transmission mechanism for transmitting driving force to one of the rollers provided in A fulcrum is provided between a roller pressing drive mechanism for changing the card and the card waiting passage and the card return passage, and an arm extending from the fulcrum normally connects the card processing passage and the card return passage. The device is supported by a passage switching lever mechanism that rotates in conjunction with the roller pressing drive mechanism to connect the card waiting passage and the card processing passage when taking in a card, thereby making it possible to reduce the thickness of the card. In addition, the present invention provides a card processing device that can reliably take in and return cards.

Hereinafter, the present invention will be described in detail based on embodiments shown in the drawings.

〔Example〕

FIG. 1 is a basic configuration diagram of a card processing device according to the present invention.

In the figure, 1 is a card insertion slot, and 2 is a card return slot, which are provided close to each other vertically. Reference numeral 3 denotes a flexible and elastic card, on which the number of possible calls is magnetically recorded; 4, a card waiting passage whose one end communicates with the card insertion slot 1 and extends rearward almost horizontally; A card take-in mechanism 5 and a shutter mechanism 6 are arranged on the back side of the passage 4. The shutter mechanism 6 normally prevents the card 3 inserted from the card insertion slot 1 from being inserted any further. Reference numeral G designates a card processing return passageway, one end of which is connected to the card return opening 2, a midway portion of the passageway is connectable to the other end of the card waiting passageway 4, and the passageway G is connected to the card return opening 2; 2 to the middle part of the passage is a card return passage 8, and from the middle part to the middle part is a card processing passage 7, which includes a card processing conveyance mechanism (not shown) for reciprocating the card 3, and a card reading device. R, card writing device W, punching device P, etc. are provided. S ₁ is an insertion detection element consisting of a light emitting element and a light receiving element, S ₂ is a return detection element also consisting of a light emitting element and a light receiving element, and 9 is a card disposed in the card return passage 8 together with a card return mechanism (not shown). The return lever 10 is a path switching lever mechanism that characterizes the present invention. This lever mechanism 10 is a lever having a fulcrum A between the card waiting path 4 and the card return path 8, and its arm is connected to the card receiving path. Opposed to the loading mechanism 5, the card waiting passage 4 and the card processing return passage G are normally prevented from communicating with each other, and the card return passage 8 and the card processing passage 7 are made to communicate with each other. Note that H is a card ejection port for removing the card 3 if it becomes jammed in the card processing path 7.

FIGS. 2 and 3 are control circuits and operation timing diagrams of the card processing device configured in FIG. 1.

A series of operations of the card processing device will be briefly explained based on these figures. When the user inserts the card 3 into the card insertion slot 1, the insertion detection element _S1 detects this, and the detection signal drives the card intake mechanism 5 and the card transport mechanism simultaneously or at short intervals. The card 3 is the card receiving mechanism 5
The card is taken into the card take-in passageway 4, and its front end abuts against the shutter mechanism 6 to prevent further entry. Next, in response to a command from the microprocessor 20, the card taking-in mechanism 5 moves downward as shown by the arrow in FIG. 1 to push down the front end of the card 3. Then, the front end of the card 3 is bent due to its own flexibility. At the time of this taking in, the lever mechanism 10 is rotated downward by or in conjunction with the card taking mechanism 5, thereby communicating the card waiting passage 4 with the card processing passage 7. Further, the shutter mechanism 6 moves upward to release the prevention of the card 3 from entering. Therefore, the card 3 is guided to the card processing path 7 by the card taking mechanism 5. The card loading mechanism 5
is restored after guiding the card 3 to the card processing passage 7, leaving the card standby passage 4 in an empty state. At the same time, the shutter mechanism 6 and lever mechanism 10 are also restored.
Allows insertion of a spare card. The card 3 advances through the card processing path 7 by a card processing transport mechanism, and the information recorded on the card is read by a reading device R and sent to the microprocessor 20.
is stored in the memory 21 of. If there is a service possibility, the number of degrees in the memory 21 is first reduced by one (corresponding to the charge being taken in advance by one degree), and the service is started. Eventually 1
When the service time corresponding to the number of degrees has elapsed, the number of degrees is decremented by one again and the service is continued. If a spare card (second card) is inserted during the service, _S1 detects this and the memory 21 stores this state. As the service progresses, the frequency decreases to 0.
At this time, the card 3 is written with the number 0 by the card writing device W, and after a punch indicating that there is no remaining number is punched by the punch device P, the card 3 is sent to the card return path by the card processing and conveyance mechanism. 8, and is returned from the card return slot 2 by the card return mechanism. When the return operation is completed, the return detection element _S2 detects this. If a spare card is not inserted into card slot 1, the service will be forcibly disconnected when the last service time has elapsed, but if a spare card is inserted, The card capturing mechanism 5 and the card processing and transporting mechanism perform the card capturing operation again, so that the service is continued. Note that the card processing transport mechanism drive motor, punching device, etc. shown in FIG. 3 are controlled by a microprocessor 20 based on instructions from a memory 21.

FIGS. 4a and 4b are a side sectional view and a perspective view of essential parts showing a first embodiment embodying the present invention. The card waiting passage 4 and the card processing passage 7 are set at substantially the same height. Reference numeral 25 denotes a card pressing roller, and this roller 25 is pivotally supported by a rotating lever 26 that uses a fulcrum B as a rotating fulcrum. The rotary lever 26 has a card intrusion prevention portion 26a that constitutes the shutter mechanism 6 integrally at one end thereof, and is rotated counterclockwise about the fulcrum B by a drive device 27 such as a solenoid during the loading operation. As a result, the roller 25 is pressed against the card 3. A roller 30 is disposed directly below and opposite the roller 25, and these rollers 25 and 30 constitute a card take-in roller mechanism 5. A pulley 54 is fixed to the shaft 55 of the roller 30, and a belt 28 is stretched between this pulley 54 and another pulley 53 fixed to another shaft 55A.

Reference numerals 32 and 33 denote conveyor belts constituting the card conveyance mechanism 23, and the front end of the lower belt 33 extends into the card return path 8 and is stretched around another pulley 31 disposed on the shaft 55A. Therefore, it also serves as the card return mechanism 24. 34 to 36 are rollers; 37 to 40 are pressure rollers for applying pressure in the directions of the arrows to opposing rollers or belts; 41 to 43 are tension rollers for applying tension to the belts 32 and 33; 44 and 45 are pressure rollers for applying tension to the belts 32 and 33; A support mechanism 4 to which the various mechanisms, belts, rollers, etc. are attached.
6 and 47 are card transport support surfaces; 48 is a motor for driving the card take-in roller mechanism 5, card transport mechanism 23 and card return mechanism 24;
The rotational force of the motor 48 is transmitted to the roller 35 via a belt 50 and a pulley 51 (driving force transmission mechanism) shown by a dashed line.

The rotation of the pulley 31 is transmitted to the pulley 53 via the shaft 55A, and the rotation of the pulley 53 is transmitted to the pulley 54 via the belt 28. Rotation of the pulley 54 is transmitted to the roller 30 via the shaft 55. In this way, the rotation of the motor 48 is also transmitted to the card take-in roller mechanism 5.

In this case, the card taking-in roller mechanism 5 includes vertically opposed rollers 25, as shown in FIG.
30 and a pressure roller 61 that presses the roller 30.
The pressure roller 61 may be pressed against the roller 31 via the belt 33. It is assumed that force is applied to the pressure roller 61 in the direction of the arrow.

In FIG. 4, the card return lever 9 and passage switching lever mechanism 10 are the same as in FIG. 1.
In such a configuration, the operation of taking in and returning the card 3 will be explained. The card 3 inserted from the card insertion slot 1 comes into contact with the card intrusion prevention part 26a of the rotating lever 26 and is stopped. When the drive device 27 operates, the rotary lever 26 is rotated counterclockwise about the fulcrum B, so that the card intrusion preventing portion 26a rises to release the intrusion prevention of the card 3.

At the same time, the card pressing roller 25 descends to press the card 3 against the roller 30. Then, the card 3 is transferred to the right, taken in, and guided to the card processing passage 7. At the time of taking in the card, the passage switching lever mechanism 10 is rotated clockwise in conjunction with the card taking-in roller mechanism 5, causing the card waiting passage 4 and the card processing passage 7 to communicate with each other.
After passing, the original state is restored.

After the call ends, the card transport mechanism 23 moves the card 3 in the opposite direction to the insertion direction and returns it to the card return path 8.
and deliver it to the card return mechanism 24,
Return the card through card return slot 2. At this time, the card return lever 9 rotates counterclockwise about the rotational fulcrum D because the slope E on the path switching lever mechanism 10 side that constitutes the chevron-shaped upper surface is pressed by the card 3. The card return passage 8 is opened and the card 3 can be returned. When the card 3 passes through the slope E, the card return lever 9 is rotated back by the force of the spring 65, and the card return passage 8 is closed. During this rotational return, the end of the card 3 is pushed out by the slope F of the card return lever 9 on the card return port 2 side, and is separated from the belt 33 and roller 37. The front end surface J of the lever 9 prevents the card 3 from being reversely inserted from the card return slot 2 after the lever 9 returns.

In FIG. 4, the lever mechanism 10 is rotated to the right by a mechanism not shown in conjunction with the depression of the roller 25 and the rotating lever 26, thereby connecting the card waiting passage 4 and the card processing passage 7. It may be driven to do so. An advantage of doing so is that if the card 3 conveyed to the card processing path 7 is abnormal, the card 3 can be returned not only from the return slot 2 but also from the insertion slot 1. That is, when an abnormal card becomes jammed in the processing passage, the roller 25 is pushed down, the passage switching lever mechanism 10 is rotated to the right, the card waiting passage 4 and the card processing passage 7 are connected, and the motor 48 is rotated in the opposite direction. Cards in the processing path 7 can be guided to the insertion slot 1.

Here, in the Y-shaped passage, card 3 is usually
It flows in the following order: card waiting passage 4 card processing passage 7 card return passage 8 . However, since the passage must be changed, the card 3 is likely to become clogged, and countermeasures are required. In the present invention, as described above, the path switching lever mechanism 10 operates in conjunction with the card take-in roller mechanism 5.

Thereby, the flow of cards 3 can be controlled in various ways. In FIG. 1 or 4, consider the case where the card 3 in the card processing passage 7 is returned from the card insertion slot 1. When the drive device 27 is operated and the card pressing roller 25 is pressed against the roller 30, the card intrusion preventing portion 26a moves upward and the shutter mechanism 6 opens, and the lever mechanism 10 moves clockwise. , the card waiting passage 4 is connected to the processing passage 7. Here, the rollers 30, 3
8, 34, etc., in the direction in which the card is returned, first the card in the card waiting passage 4 is returned from the insertion slot, and then the card in the card processing passage 7 passes through the card waiting passage 4 and returns the card. It is returned from insertion slot 1. In this way, if you are unable to return your card through the return slot due to a defective card, etc.
You can also return the card through card insertion slot 1.

FIG. 6 shows a second embodiment of the present invention, in which a is a side view of a state in which a processed card is returned with a spare card waiting for insertion, b is a side view of the main part showing a card loading state, and c is a side view of a state in which a processed card is returned. d is a perspective view of the main part, and d is a side view of the main part showing the inserted state of the bent card. In this embodiment, the card waiting passage 4 is formed by a pair of upper and lower card insertion support plates 70 and 71, and the lower card insertion support plate 7
A pair of left and right extensions 71A that extend horizontally along the passageway 4 and have elasticity are integrally provided at the rear end of the card 1, and a stopper 72 for inhibiting card insertion is integrally provided at the tips of these extensions 71A. As a result, the shutter mechanism 6 and the passage switching lever mechanism 10 can be used together. Reference numeral 73 denotes a permanent magnet disposed on the rotary lever 26 to attract the stopper 72, and 74 is a member similarly attached to the rotary lever 26 with which the stopper 72 abuts and engages.

It should be noted that the other configurations are almost the same as those of the first embodiment, so the same components are designated by the same reference numerals and their explanations will be omitted.

Next, the card loading operation will be explained. The card 3 inserted from the card insertion slot 1 comes into contact with the stopper 72 and is stopped. Driven by the drive device 27, the rotary lever 26 rotates counterclockwise about the fulcrum B to move the card pressing roller 25 to the extension portion 7.
1A through the card 3, the extension part 71A is elastically deformed downward about its base K as a fulcrum, as shown in FIG. At the same time, since the extension part 71A constitutes the lever mechanism 10, the card standby passage 4 and the card processing passage 7 are communicated with each other by elastic deformation downward, thereby enabling the card transport mechanism 23 to take in the card 3.

Here, to describe the advantages of this embodiment, the card 3 inserted into the card waiting passage 4 is
Card pressing roller 25, lower surface 26a of rotary lever 26, upper surface of extension portion 71A, and stopper 7
Since the card 3 is supported from three sides by the card 2, the degree of freedom of movement of the card 3 is small, and therefore the normal card intrusion prevention function is reliable.

Further, the displacement required for the pressing operation of the card pressing roller 25 is determined by the thickness of one card and the extension portion 7.
It is only the sum of the thicknesses of 1A. Thickness of card 3
0.3 to 0.4 mm, and the thickness when the extension part 71A is made of a metal plate is ~0.5 mm, the required displacement is 1 in total.
It is about mm. Furthermore, since the length between the point where the roller 25 acts on the card 3 and the fulcrum B of the rotating lever 26 is longer than the length between the fulcrum B and the point of action C of the drive device 27, the drive displacement of the drive device 27 is enlarged by the rotating lever 26. For the above reasons, the drive device 27 may be a device that generates a small displacement.

Furthermore, since the length of the extension part 71A, that is, the length from the base K of the extension part 71A to the stopper 72, is longer than the length between the base K and the point of action of the roller 25, during the pressing operation of the roller 25, The displacement is magnified by the extension 71A and transmitted to the stopper 72. Therefore, the function of preventing card intrusion by the stopper 72 is reliably canceled during the card taking-in operation.

Regarding the card return operation, since the stopper 72 and the extension part 71A form a guide for guiding the card 3 to the card return path 8, a reliable return is performed.

Next, detection of a bent card and its processing will be described.

The extension part 17A is connected to the card waiting passage 4 and the card processing passage 7 by means of a fulcrum K which normally has spring properties.
and are kept separate. In the figure, the clockwise rotating force is applied to the extension part 71 by the fulcrum K.
A, and the stopper 72 is pressed against a member 74 attached to the rotating lever 26. If the bending of the inserted card 3 is smaller than the spring force of the fulcrum K, there is no problem as the state shown in Fig. 6a is maintained;
2 may be separated from the member 74.
In this case, the normal card intrusion prevention function of the stopper 72 will be degraded. To prevent this, a permanent magnet 73 is provided near the member 74 to attract the stopper 72. In this case, as shown in FIGS. 6a and 6b, the card receiving operation is performed by rotating the member 74 as the rotary lever 26 rotates.
This is done by separating the stopper 72 from the permanent magnet 73 with a strong force, and then causing the roller 25 to displace the stopper 72 by a large amount. In this way, the permanent magnet 73
By using , it is possible to handle cards with large bends. However, if the card 3 is bent due to plastic deformation exceeding the allowable value, the stopper 72 may be separated from the permanent magnet 73 and the member 74 due to this bending force. This situation is shown in FIG. 6d. 78 is a bent portion of the card. Even if such a card 3 is taken in, it may get jammed, and a large conveying force is required to prevent it from getting jammed, so it is desirable to detect it as a fraudulent card and not take it in. 79 is a photocoupler that detects this. The figure shows a case where it is embedded in a permanent magnet 73. Light is irradiated onto the upper surface I of the stopper 72 by an LED, and the reflected light is detected using a light receiving element. When the stopper 72 is pressed against the member 74, the intensity of the reflected light is strong, but when the stopper 72 is separated from the member 74 as shown in d of the figure, it becomes extremely weak. An illegally bent card can be detected from this difference in reflected light intensity.

FIG. 7 is a side sectional view showing a third embodiment of the present invention, in which the card processing passage 7 is bent downward from the middle of the second embodiment shown in FIG. 6, resulting in a vertical device configuration. In the figure, 90 is a roller, and 91 is a pressure roller that provides card conveying force. The operations for taking in and returning the card 3 have already been explained in FIG. 6, and will therefore be omitted. The support mechanism 45 to which the roller group is attached is supported so as to be able to rotate clockwise about L as a fulcrum. This opens the card processing passage 7 and allows cleaning of the passage 7 and the reading/writing device R/W. Although the card processing passage 7 is bent downward in FIG. 7, it is also possible to bend it upward, insert the card 3 from the bottom of the device, and return it. Components that are the same as those in FIGS. 4 and 6 are designated by the same reference numerals, and their explanations will be omitted.

FIG. 8 shows a fourth embodiment of the present invention, in which the rollers are made more economical in comparison with the embodiment shown in FIG. In the figure, 100 is a composite roller that performs the functions of rollers 30, 31, and 90 in FIG. 7, 101 is a transport drive roller, and 102 is a motor 4
8 is a gear mechanism that transmits the rotational force to the roller 101, and 103 is a return lid. In addition, figure a shows how the card is inserted, figure b shows how the card is taken in,
c shows how the card is returned.

9a, b, and c are a side view of a main part, a perspective view of a main part, and a side view of a main part when a card is taken in, showing a fifth embodiment of the present invention. In this embodiment, the extension part 71A is formed of a bimolov piezoelectric element, and a flat bimolov piezoelectric element 110 is attached to the upper card insertion support plate 70 to form the card waiting passage 4. . A card pressing roller 25 is disposed on the bimolov piezoelectric element 110, and the lower part thereof is connected to the card waiting passage 4.
is coming.

To briefly explain the card taking-in operation, a stopper 72 is attached to the tip of the extension portion 71A to prevent the card 3 from entering.
When a voltage is applied to the extension part 71A and the bimolov piezoelectric element 110 when taking in a card, these bend downward as shown in Figure c, releasing the card entry prevention and pushing the card 3 onto the card pressing roller 25.
is pressed against the roller 30. Therefore, the card 3 is taken into the card processing passage 7 from the card waiting passage 4.

Although the above embodiment has been described with reference to a case where the card is applied to a magnetic card public telephone in which the card functions as a cash voucher, the present invention is not limited to this, but is also suitable for use in public faxes, vending machines, etc. that use cards. In addition to the magnetic card, the card may be an optical card as long as it has flexibility and elasticity.

〔Effect of the invention〕

As explained above, the card processing device according to the present invention is configured so that the card insertion slot and the card return slot are provided in close proximity to each other, so that the device itself can be made thinner, and when the card is returned, the user can easily return the card. It is possible to easily recognize the card, prevent forgetting the card, and improve serviceability. Further, the present invention has a fulcrum between the card waiting passage and the card return passage, and an arm extending from the fulcrum normally cuts off communication between the card waiting passage and the card processing passage, and connects the card return passage with the card return passage. The structure includes a lever mechanism that communicates with the card processing passage and operates in conjunction with the card taking operation to communicate the card waiting passage with the card processing passage, so that it does not clog cards whose degree of bending is within the permissible range. The card is reliably taken in without being damaged, and the return operation is also reliable. Even if a spare card is inserted during processing, it will not be taken in by mistake, improving the reliability of the device. In particular, the arm part is made of piezoelectric elements. In some cases, low power acquisition is possible. Furthermore, the roller pressing drive mechanism and the passage switching lever mechanism operate in conjunction, making it possible to return cards from either the card insertion slot or the card return slot. The effect is very great, such as being able to return cards in the processing passage from the card waiting passage.

[Brief explanation of drawings]

FIG. 1 is a basic configuration diagram of the present invention, FIGS. 2 and 3 are control circuits and operation timing diagrams of the card processing device configured in FIG. 1, and FIGS. 5 is a side view showing another embodiment of the card taking mechanism, FIG. 6 is a second embodiment of the present invention, and a shows a spare card. A side view of a state in which a processed card is returned in a state of waiting for insertion, b is a side view of the main part showing the card loading state, c is a perspective view of the main part,
d is a side view of the main part showing the inserted state of the bent card, FIG. 7 is a side sectional view showing the third embodiment of the present invention, and FIG.
The figures show the fourth embodiment of the present invention, where a shows how the card is inserted, b shows how the card is taken in, and c shows how the card is returned. FIG. 2 is a side view and a perspective view of a main part showing an example. 1...Card insertion slot, 2...Card return slot, 3
... Card, 4 ... Card waiting passage, 5 ... Card take-in roller mechanism, 6 ... Shutter mechanism, 7
...Card processing aisle, 8...Card return aisle, 9
... Card return lever, 10 ... Path switching lever mechanism, 23 ... Card transport mechanism, 24 ... Card return mechanism, 72 ... Stopper, 110 ... Bimolov piezoelectric element, G ... Card processing return path.

Claims (1)

[Claims] 1. A card insertion slot, a card return slot provided adjacent to the card insertion slot, a card waiting passageway with one end connected to the card insertion slot, and a card waiting passageway with one end connected to the card return slot, and a card return slot provided near the card insertion slot. A middle part of the passage is provided so as to be connectable to the other end of the card waiting passage, the part from the card return opening to the middle part of the passage is a card return passage, and the part beyond the middle part is a card processing passage. a passage, a card take-in roller mechanism provided above and below the card waiting passage so as to face each other with a gap at least equal to the thickness of the card, and a shutter mechanism provided near an end of the card waiting passage; A card transport mechanism for moving the card along the card processing return path, and a drive for transmitting a part of the driving force of this card transport mechanism to one of the rollers provided at the top or bottom of the card waiting path. a force transmission mechanism; a roller pressing drive mechanism for changing a card waiting passage into a card taking passage by pressing a roller to which driving force is not being transmitted against a driven roller; A fulcrum is provided between the standby passage and the card return passage, and an arm extending from the fulcrum is normally supported to connect the card processing passage and the card return passage, and when a card is taken in, the arm is supported by the roller. A card processing device comprising a passage switching lever mechanism that rotates in conjunction with a stop drive mechanism to connect a card standby passage and a card processing passage.